Studying structural and local dynamics in model H-bonded active ingredient - Curcumin in the supercooled and glassy states at various thermodynamic conditions.

Different experimental techniques were applied to study thermal and structural properties, strength of H-bonds, possible keto-enol tautomerism and molecular dynamics at various thermodynamic conditions in the H-bonded active substance, curcumin (CRM). Dielectric measurements revealed dynamical features of examined compound that are uncharacteristic for the associated systems. This includes enormously large pressure coefficient of the glass transition temperature and prominent drop of the fragility with compression. Simultaneously, the shape of α-process slightly broadened at elevated pressures. Infrared investigations demonstrated that this effect is related to the variation in the population of H-bonds. Moreover, we studied the changes in the structural and dynamical properties of the glasses prepared upon cooling of the melt (ordinary glass, OG) and the one obtained after compression of CRM in the liquid phase and decompression at T = 293 K (dense glass, DG). Interestingly, during the aging of the latter sample, a clear shift of the ß-relaxation towards higher frequencies was noted. This unexpected result indicated that the density of DG is probably getting smaller with time. Complementary X-ray diffraction experiments confirmed this supposition. Additionally, they showed that in DG there are traces of polymorph II of CRM that has a higher density than initial crystals (polymorph I). Finally, infrared studies demonstrated that H-bond pattern in DG is slightly different with respect to OG. Furthermore, Raman investigations suggested that probably keto-enol tautomerism might be shifted towards diketo form in the glass obtained at high compression. Our investigations are very interesting in the context of better understanding of the behavior of associated systems at high compression as well as provide a better insight into dynamics of higher density glasses produced at elevated pressures.

Efficient metal-free strategies for polymerization of a sterically hindered ionic monomer through the application of hard confinement and high pressure.

In this paper, we have studied the effect of both hard confinement (nanoporous membranes treated as nanoreactors) and high pressure (compression of system) on the progress of free-radical (FRP) and reversible addition-fragmentation chain transfer (RAFT) polymerizations of selected hardly polymerizable, sterically hindered imidazolium-based ionic monomer 1-octyl-3-vinylimidazolium bis(trifluoromethanesulfonyl)imide ([OVIM][NTf2]). These two innovative approaches, affecting (in a different way) the free volume of the polymerizing system, allows the reduction of the number of toxic substrates/catalysts, satisfying the requirement of green chemistry. It was found that at both conditions (high compression and confinement) the polymerizability of monomer, as well as the control over the reaction and the properties of the produced polyelectrolytes, have increased significantly. However, it should be added that there were noticeable differences between FRP carried out under confinement and at high pressures. Interestingly, by appropriate variation in thermodynamic conditions, it was possible to synthesize polymers of moderate molecular weight (M n ∼ 58 kg mol-1) and relatively low dispersity (D ∼ 1.7); while for the reaction performed within AAO pores of varying diameter (d = 35 nm and d = 150 nm), macromolecules of higher M n but slightly broader dispersity indices (D ∼ 2.2-2.7) were recovered. On the other hand, RAFT polymerization carried out under confinement and at elevated pressures yielded polymers with well-defined properties. Noteworthy is also the fact that nanopolymerization leads to polymers of comparable M n to those obtained at high-pressure studies but at significantly shorter reaction time (t ∼ 2 hours). We believe that the presented data clearly demonstrated that both examined approaches (the compression and application of alumina templates, treated as nanoreactors) could be successfully used as additional driving forces to polymerize sterically hindered monomers and produce well-defined polymers in relatively short times. At the same time, it should be mentioned that both proposed polymerization methods enabled us to omit the addition of metal-based initiators/catalysts, which seem to be a crucial step towards further development of the alternative green synthesis of polyelectrolytes in the future.

Conformational changes underlying variation in the structural dynamics of materials confined at the nanometric scale.

Broadband dielectric and Raman spectroscopies combined with calorimetric measurements and DFT calculations have been used to investigate the molecular dynamics of the benzyl derivative of ibuprofen (Ben-IBU) incorporated into aluminum oxide (AAO) templates of various pore diameters (d = 20 nm and d = 80 nm). Time-dependent experiments on the material confined in pores of d = 20 nm revealed the occurrence of a low activation barrier kinetic process, that was manifested as a variation in the integral intensities of some characteristic vibrations of carboxylic and benzene moieties as well as a shift of the structural relaxation process. Complementary DFT computations enabled us to identify its molecular nature as originating from cis to trans like conformational change. Our results clearly show that molecular rearrangements enforced by the interactions with the pore walls/substrate may affect the properties of the confined systems. Consequently, these effects must be taken into account to understand the dynamics and variation of the glass transition temperature in high (polymers) and low molecular weight glass formers subjected to spatial restrictions at the nanometer scale.

Unusual dielectric response of 4-methyl-1,3-dioxolane derivatives.

In this paper, we applied broadband dielectric spectroscopy (BDS) to investigate the molecular dynamics of three 4-methyl-1,3-dioxolane derivatives (MD) whose chemical structures differ in the length of non-polar alkyl side chains. We notice that small changes within their chemical structures have a pronounced impact on parameters characterizing the supercooled dynamics of the compounds selected for this study. Our detailed analysis of the dielectric response reveals that in the supercooled-liquid state besides the structural α-relaxation a sub-α Debye-like relaxation can be clearly distinguished. The observed two relaxation regimes mirror the structural complexity of the investigated MD derivatives. The amphiphilic nature of the investigated compounds and possible interactions between non-polar side chains can rationalize the observed behavior. To follow the molecular arrangement of MD derivatives at low temperatures, we also carried out Raman measurements. Additionally, we performed BDS measurements at elevated pressures which revealed that, as a result of compression, the sub-α contribution to the dielectric response disappeared. The paper concludes with a discussion of open questions about the possible molecular origin of the observed sub-α Debye-like process. These results provide fresh insight into the puzzling nature of the slow supramolecular relaxation modes in low-molecular glass forming liquids.

Impact of Intermolecular Interactions, Dimeric Structures on the Glass Forming Ability of Naproxen, and a Series of Its Derivatives.

In this article, thermal properties, molecular dynamics, crystallization kinetics, and intermolecular interactions in pure naproxen (NAP), its amide (NH2-NAP), and four esters (methyl, Met-NAP; isopropyl, Iso-NAP; hexyl, Hex-NAP; and benzyl, Ben-NAP) have been investigated using differential scanning calorimetry as well as broadband dielectric and Fourier transform infrared spectroscopies. We found that the modification of the NAP molecule by substituting a hydrogen atom from the hydroxyl group strongly inhibits the crystallization tendency of this active pharmaceutical ingredient (API) and simultaneously increases its glass forming ability (GFA). In this context, it is worthwhile to stress that pure naproxen and its amide crystallized very quickly, regardless of the cooling rate. Therefore, these compounds cannot be classified as good glass-formers. On the other hand, ester derivatives of API can be easily vitrified. Moreover, dielectric measurements revealed that with an increasing molecular weight of the substituent, the rate of crystallization process slows down significantly. Consequently, Ben-NAP was characterized by the highest GFA among all investigated API esters. Comprehensive FTIR studies clearly indicated that the strong tendency to create dimeric structures in the nonmodified NAP and NH2-NAP is responsible for their enhanced crystallization. At the first sight, our results stay in contrast to most literature data, showing that H-bonds favor the glass formation ability. However, this effect is usually observed for the materials, which form extensive multidirectional hydrogen bonds and associates. In NAP and NH2-NAP, the situation is much different, since both compounds exist mainly as dimers. Therefore, one can postulate that specific intermolecular interactions are an important parameter determining the GFA of different materials, including APIs.

Anhydrosaccharides-A new class of the fragile plastic crystals.

In this paper, 1,6-anhydro-ß-D-glucopyranose (anhGLU), 1,6-anhydro-ß-D-mannopyranose (anhMAN), and 1,6-anhydro-ß-D-galactopyranose (anhGAL), three new materials that form the Orientationally Disordered Crystal (ODIC) phase, have been thoroughly investigated using various experimental techniques. All measurements clearly indicated that these compounds possess a series of very interesting physical properties that are considerably different than those reported for ordinary plastic crystals. X-Ray diffraction investigations have revealed enormously long-range static correlations between molecules, reaching even 120 Å. Moreover, dielectric studies showed that besides Freon 113, the investigated anhydrosaccharides are the most fragile systems that form the ODIC phase. Further analysis of Fourier transform infrared spectra indicated that such peculiar behavior of anhydrosaccharides might be closely related to multidirectional H-bonds of various strengths that most likely affect the number of available conformations, density states, and the potential barriers in the energy landscape of these compounds. This is consistent with the results from previous reports [L. C. Pardo, J. Chem. Phys. 124, 124911 (2006) and Th. Bauer et al., J Chem. Phys. 133, 144509 (2010)] showing that the higher fragility of Freon 112 as well as a mixture of 60% succinonitrile and 40% glutaronitrile (60SN-40GN) can be closely related to the enhanced conformational ability and additional disorder introduced by various substituents, which further make energy landscape more complex. Finally, by studying the properties of 2,3,4-tri-O-acetyl-1,6-anhydro-ß-D-glucopyranose (ac-anhGLU) it was found that besides the shape of the molecules, H-bonds or generally strong intermolecular interactions are extremely important parameters contributing to the ability to form the plastic phase. This is in line with current observations that in most cases the ODIC phase is created in highly interacting compounds.